ENERGY of the FUTURE - R&Z - Vol 1 No. 6, 1990

Energy of the Future

Raum & Zeit Vol 1. No. 6. 1990

Hydrogen Fracturing Process

Over the years man has used water in many ways to make his life on Earth more productive. Why not, now, use water as fuel to power our cars, heat our homes, fly our planes or propel spaceships beyond our galaxy? Biblical prophecy foretells this event. After all, the energy contained in a gallon of water exceeds 2.5 million barrels of oil when equated in terms of atomic energy. Water, of course, is free and abundant. The Hydrogen Fracturing Process dissociates the water molecule by way of voltage stimulation, ionizes the combustible gases by light exposure and, then, prevents the formation of the water molecule during thermal gas ignition...releasing thermal explosive energy beyond "normal" gas burning levels under controlled state.

Circuit Component Interaction:

Pulsing Transformer

The pulsing transformer (a/g) steps up voltage amplitude or voltage potential during pulsing operations. The primary coil is electrically isolated (no electrical connection between primary and secondary coil) to form Voltage Intensifier Circuit (AA). Voltage amplitude or voltage potential is increased when secondary coil (a) is wrapped with more turns of wire. Isolated electrical ground (j) prevents electron flow from input circuit ground.

Blocking Diode

Blocking diode (b) prevents electrical "shorting" to secondary coil (a) during pulse-off time since the diode "only" conducts electrical energy in the direction of the schematic arrow.

LC Circuit

Resonant Charging Choke (c) in series with Excitor-Array (E1/E2) forms an inductor-capacitor circuit (LC) since the Excitor-Array (ER) acts or performs as a capacitor during pulsing operations. The dielectric properties (insulator to the flow of amps) of natural water (dielectric constant being 78.54 @ 25c) between the electrical plates E1/E2) forms the capacitor (ER). Water now becomes part of the VIC in the form of "resistance" between electrical ground and pulse-frequency positive-potential...helping to prevent electron flow within the pulsing circuit (AA) of Figure 1-1.

The inductor (c) takes on or becomes a Modulator Inductor which steps up an oscillation of a give charging frequency with the effective capacitance of a pulse-forming network in order to charge the voltage zones (E1/E2) to a higher potential beyond applied voltage input. The inductance (c) and Capacitance (ER) properties of the LC circuit is therefore "tuned" to resonance at a certain frequency. The Resonant Frequency can be raised or lowered by changing the inductance and/or the capacitance values. The established resonant frequency is, of course, independent of voltage amplitude, as illustrated in Figure 9BB as to Figure 16A.

The value of the Inductor (C), the value of the capacitor (ER), and the pulse-frequency of the voltage being applied across the LC circuit determines the impedance of the LC circuit.

The impedance of an inductor and a capacitor in series, Z is given by:

Where:

Ohm's law for LC circuit in series is given by:

LC Voltage

The voltage across the inductor (c) on capacitor (ER) is greater than the applied voltage (h). At frequency close to resonance, the voltage across the individual components is higher than the applied voltage (h), and, at resonant frequency, the voltage Vt across both the inductor and the capacitor are theoretically infinite. However, physical constraints of components and circuit interaction prevent the voltage from reaching infinity. The voltage (Vl) across the inductor (C) is given by the equation:

The voltage (Vc) across the capacitor is given by:

During resonant interaction, the incoming unipolar pulse-train (h) of Figure (1-1) as to Figure (9B) produces a step-charging voltage-effect across Excitor-Array (ER), as illustrated in Figure (9BB) and Figure 16A. Voltage intensity increased from zero "ground-state" to a high positive voltage potential in a progressive function. Once the voltage-pulse is terminated or switched-off, voltage potential returns to "ground-state" or near ground-state to start the voltage deflection process over again. Voltage intensity of level across Excitor-Array (ER) can exceed 20,000 volts due to circuit (AA) interaction and is directly related to pulse-train (h) variable amplitude input.

RLC Circuit

Inductor (C) is made of or composed of resistive wire (R2) to further restrict D.C. current flow beyond inductance reaction (XL), and is given by:

Dual Inline RLC Network

Variable inductor-coil (d), similar to inductor (C) connected to opposite polarity voltage zone (E2) further inhibits electron movement or deflection within the VIC. Moveable wiper arm fine "tunes" "Resonant Action" during pulsing operations. Inductor (d) in relationship to inductor (C) electrically balances the opposite voltage electrical potential across voltage zone (E1/E2).

VIC Resistance

Since pickup coil (A) is composed of or made of resistive wire-coil (R1), then total circuit resistance is given by:

Where, Re, is the dielectric of natural water